TW201739106A - Array dipole antenna device and dipole antenna wherein the array dipole antenna device can be applied to the multi-input multi-output (MIMO) wireless communication system, and the dipole antenna has the characteristics of small volume and good gain - Google Patents

Abstract

The present invention discloses an array dipole antenna device and a dipole antenna. The dipole antenna includes a first antenna body and a second antenna body respectively arranged at opposite sides of a substrate. The first antenna body includes two first antenna portions and a first microstrip line portion connected between the two first antenna portions. Each of the first antenna portions has a first high-frequency radiation arm in an L shape, and a first low-frequency radiation arm in an L shape, which are connected with each other. The second antenna body includes two second antenna portions and a second microstrip line portion connected between the two second antenna portions. The configuration and position of the second antenna portions are in mirror symmetry with those of the first antenna portions, respectively, along a mirror symmetry line. With this structural design, the dipole antenna has the characteristics of dual wideband and good gain under the miniaturization.

Description

Array dipole antenna device and dipole antenna

The invention relates to an antenna, in particular to a dipole antenna.

With the advancement of wireless communication technology, many countries have begun to build wireless local area network in important cities or public spaces. Some families have begun to establish wireless local area networks, such as Wi-Fi networks, wireless LANs and WLANs. People can connect to wireless local area networks in offices, homes, and public places (such as airports, restaurants, cafes, hotels, and universities) with computers or smart mobile devices for fast and easy data transfer.

Because the MIMO (Multi-input Multi-output) communication system can independently transmit and receive signals by using multiple antennas, and can increase the data throughput without increasing the bandwidth or the total transmit power consumption (throughput) And the transmission distance, so it has gradually attracted attention in recent years, but how to reduce and simplify the integration of the antenna used in the MIMO communication system without affecting the communication quality is the current goal of many antenna manufacturers.

Accordingly, it is an object of the present invention to provide an array dipole antenna device for a multiple input multiple output wireless communication system.

Another object of the present invention is to provide a dipole antenna that is small in size and has better gain characteristics.

Therefore, the array dipole antenna device of the present invention comprises a pedestal, a reflective frame erectably disposed on the top surface of the susceptor, and a plurality of reflective frames disposed on the top of the pedestal at intervals along the circumference of the reflective frame. Dipole antennas that face each other and are spaced apart from the reflection frame. Each of the dipole antennas includes a substrate extending horizontally and erectably disposed on a top surface of the base, and a first antenna body and a second antenna body respectively disposed on the substrate. The substrate has a first side and a second side opposite each other and defines two mirror-symmetric lines extending up and down and spaced along the lengthwise direction thereof. The first antenna body is disposed on the first side, and includes two first antenna portions disposed along the longitudinal interval of the substrate, and a first microstrip line portion connected between the first antenna portions Each of the first antenna portions has an L-shaped first high-frequency radiation arm connected to one another at one end and connected to the first microstrip line portion, and an L-shaped first low-frequency radiation arm. The second antenna body is disposed on the second side, and includes two second antenna portions disposed along the longitudinal interval of the substrate, and a second microstrip line portion connected between the second antenna portions The shape and arrangement position of each of the second antenna portions is mirror symmetrical with one of the first antenna portions along one of the mirror symmetry lines, and each of the second antenna portions has one end connected to each other and connected to the second A second high frequency radiating arm of the microstrip line portion and a second low frequency radiating arm.

Therefore, the dipole antenna of the present invention comprises a substrate, and a first antenna body and a second antenna body respectively disposed on the substrate. The substrate is in the form of an upright sheet extending left and right, having a first side surface and a second side surface opposite to each other, and defining two mirror-symmetric lines extending up and down and spaced apart from each other. The first antenna body is disposed on the first side, and includes two first antenna portions spaced apart from each other, and a first microstrip line portion connected between the first antenna portions at both ends thereof, Each of the first antenna portions has an L-shaped first high-frequency radiating arm connected to one another at one end and connected to the first microstrip line portion, and an L-shaped first low-frequency radiating arm. The second antenna body is disposed on the second side, and includes two second antenna portions spaced apart from each other, and a second microstrip line portion connected between the second antenna portions, each second The outer shape and the installation position of the antenna portion are mirror symmetrical with one of the first antenna portions along one of the mirror symmetry lines, and each of the second antenna portions has one end connected to each other and connected to the second microstrip line portion. A second high frequency radiating arm and a second low frequency radiating arm.

The utility model has the advantages that the structure design of the dipole antenna enables the dipole antenna to have double wide frequency band and good gain characteristics in a miniaturization case, and can further cooperate with the design of the reflection frame, and can be applied. For WLAN and Multiple Input Multiple Output (MIMO) wireless communication systems.

Before the present invention is described in detail, it should be noted that in the following description, similar elements are denoted by the same reference numerals.

Referring to Figures 1, 2 and 3, the first embodiment of the array dipole antenna device of the present invention has dual-band communication function and is suitable for application in a multi-input multi-output (MIMO) wireless communication system.

The array dipole antenna device comprises a plate-like base 3, an annular reflection frame 4 fixedly mounted on the top surface of the base 3, and a plurality of spacers fixed on the top surface of the base 3 and spaced around the reflection frame 4 Distributed dipole antenna 5. For convenience of explanation, in the following description, the left and right sides of FIG. 2 are defined as the left and right direction, and the front side of FIG. 2 is defined as the front and rear direction.

The reflective frame 4 is a metal quadrangular ring frame fixed in the center of the base 3, and has four upright fixed to the base 3, and is reflective to block the signals from the dipole antennas 5. The reflective wall 41 can improve the signal gain of the entire array dipole antenna device by the reflection function of the reflective walls 41.

With the pedestal 3 and the reflection frame 4 being externally configured, four dipole antennas 5 are disposed in the embodiment, and the dipole antennas 5 are vertically symmetrically disposed on four sides of the top surface of the pedestal 3, And distributed around the reflective frame 4, and respectively spaced apart toward one of the reflective walls 41, and the top edges of the dipole antennas 5 are lower than the top edges of the reflective walls 41.

Referring to Table 1, in the present embodiment, the height of the entire array dipole antenna 5 is H3. The base 3 has a length of four sides of L7. The reflective walls 41 of the reflection frame 4 have a length L8 and a height H2. The dipole antennas 5 have a length L1 and a height H1. The distance between each dipole antenna 5 and the opposing reflective wall 41 is D, and the shortest distance between two adjacent dipole antennas 5 is V. The array dipole antenna device has an overall volume of 120 x 120 x 14 mm ³ .

Since the dipole antennas 5 have the same structure, for convenience of explanation, the following description will be made by taking the dipole antenna 5 disposed on the rear side of the reflection frame 4 as an example.

The dipole antenna 5 includes a substrate 50 that is vertically erected on the pedestal 3 and a first antenna body 51 and a second antenna body 52 that are respectively disposed on the front and rear sides of the substrate 50. The substrate 50 has a second side 502 and a first side 501 opposite to each other, and defines two mirror symmetry lines 500 extending vertically up and down and spaced apart along the long side of the length. In this embodiment, the substrate 50 is made of glass fiber and has a thickness of 1 mm, and the first antenna body 51 and the second antenna body 52 are both made of copper foil and have a thickness of 35 μm. However, in the implementation, the substrate 50, the first antenna body 51, and the second antenna body 52 have a large number of material types, and thus are not limited to the above embodiments.

The first antenna body 51 is disposed on the first side surface 501, and has two C-shaped first antenna portions 511 that are symmetrically spaced apart from each other and generally open upwards, and one left and right extensions are respectively The first microstrip line portion 518 is connected to the first antenna portions 511. The first antenna portions 511 are respectively disposed on the left side of the mirror symmetry lines 500, and the first microstrip line portions 518 are substantially interposed between the mirror symmetry lines 500.

Each of the first antenna portions 511 has an L-shaped first high-frequency radiating arm 512 connected at one end thereof to the end of the first microstrip line portion 518, and one end connected to the first high-frequency radiating arm at one end thereof An L-shaped first low frequency radiating arm 515 is provided at the end of the 512 and connected to the end of the first microstrip line portion 518. The first high frequency radiating arm 512 has a first high frequency longitudinal section 513 extending up and down and connected at its bottom end to the end of the first microstrip line portion 518, and a top level from the first high frequency longitudinal section 513 A first high frequency lateral segment 514 that faces away from the corresponding mirror symmetry line 500 is extended. The first low frequency radiating arm 515 has a first low frequency lateral section 516 extending left and right with its right end connected to the bottom end of the first high frequency longitudinal section 513, and one extending upward from the left end of the first low frequency lateral section 516. The first low frequency longitudinal segment 517 is longer than the first high frequency lateral segment 514.

The second antenna body 52 is disposed on the second side surface 502, and has the same structure as the first antenna body 51, and includes two C-shaped second and right symmetrical openings and an upwardly facing C-shape. The line portion 521 extends from the left and right sides and is connected to the second microstrip line portion 528 of the second antenna portions 521 at both ends thereof. The second antenna portions 521 are respectively disposed on the right side of the mirror symmetry lines 500, and the second antenna portions 521 are disposed along the mirror symmetry lines 500 and the first antenna portions 511. The mirror image is symmetrical, and the second microstrip line portion 528 substantially overlaps the first microstrip line portion 518. Each of the second antenna portions 521 has an L-shaped second high-frequency radiating arm 522, and an L-shaped second low-frequency radiating arm 525 connected to the second high-frequency radiating arm 522, the second high-frequency radiation The arm 522 structure has a second high frequency longitudinal section 523 and a second high frequency lateral section 524. The second low frequency radiating arm 525 has a second low frequency lateral section 526 and a second low frequency longitudinal section 527.

When the dipole antenna 5 is used, the first low frequency radiating arm 515 is matched with the second low frequency radiating arm 525 to control the low frequency communication frequency, and the shorter first high frequency radiating arm is used. 512 cooperates with the second high frequency radiating arms 522 to control the high frequency communication frequency.

In this embodiment, the substrate 50 has a length L1 and a height H1. The lengths of the first low frequency longitudinal segments 517 and the second low frequency longitudinal segments 527 are L2, and the lengths of the first high frequency lateral segments 514 and the second high frequency lateral segments 524 are L3, the first The length of the low frequency transverse section 516 and the second low frequency lateral section 526 is L4, the first high frequency longitudinal section 513 and the second high frequency longitudinal pair length are L5, and the first low frequency longitudinal section 517 and the The width of the second low frequency longitudinal section 527 is W2, the width of the first high frequency lateral section 514 and the second wide frequency transverse section is W3, the first low frequency lateral section 516 and the second low frequency transverse section The width of 526 is W4, and the distance between the adjacent first low frequency longitudinal section 517 and the second low frequency longitudinal section 527 is S1. The length of the first microstrip line portion 518 and the second microstrip line portion 528 is L6.

In the implementation, the optimum low frequency band range and the optimal high frequency band range can be tested by adjusting the length and width dimensions of the first antenna portions 511 and the portions of the second antenna portions 521. Since there are numerous ways to test various sizes to find the optimum low band range and high band range, and are not the improvement points of the present invention, they will not be described in detail.

The reflection loss test and the field pattern analysis are actually performed in accordance with the size specifications of the dipole antenna 5 shown in Table 2. During testing, a 50 Ω SMA connector (not shown) is placed on the bottom edge of the substrate 50 and electrically connected to the first microstrip line portion 518 and the second microstrip line portion 528, and the frequency measuring instrument is provided. A combined vector network analyzer/spectrum analyzer (ZVL) for R&S.

Referring to Figure 4, the test results show that the low frequency reflection loss frequency range of less than -5 dB is 2.14 GHz to 2.8 GHz, the proportional bandwidth is 27.5%, and the high frequency reflection loss frequency less than -10 dB ranges from 4.41 GHz to 6 GHz. The bandwidth is 29.4%.

Further, according to the measured field patterns of 2.4 GHz, 2.5 GHz, 5 GHz, and 5.8 GHz shown in FIGS. 5A, 5B, 6A, 6B, 7A, 7B, 8A, and 8B, in the low frequency range of 2.4 GHz and 2.5 GHz, E The field pattern of the face exhibits a figure of eight, and the field pattern of the H face is due to the first low frequency radiating arm 515, the second low frequency radiating arm 525, and the first microstrip line portion 518 and the matching The bottom-designed structure of the second microstrip line portion 528 concentrates the radiation of the dipole antenna 5 upward and has directivity characteristics. In the high frequency range of 5 GHz and 5.8 GHz, the H-plane and E-plane modes are similar to those in the low frequency range of 2.4 GHz and 2.5 GHz.

From the gain curves shown in Figures 9 and 10, the low-frequency gain is approximately between 4.7 and 5.35 dBi, and the highest gain of the high-frequency is 8.06 dBi, indicating that the dipole antenna 5 has good gain characteristics.

When the array dipole antenna device of the present invention is used, when the isolation between the dipole antennas 5 is poor, mutual interference between the dipole antennas 5 affects the frequency band and gain of the fabricated array dipole antenna device. The invention is to block the reflected electric wave signal through the reflection frame 4 disposed between the dipole antennas 5, thereby reducing the degree of mutual interference, but the distance between the dipole antennas 5 and the reflection frame 4 also affects the signal reflection effect. It also affects the frequency band and gain of the entire array dipole antenna device. Therefore, by adjusting the distance between the dipole antennas 5 and adjusting the distance between the dipole antennas 5 and the reflective walls 41, the test can be performed. The effect of the low frequency band and the high frequency band is used to find the optimal size specification. Since this test portion is a prior art and is not the focus of the present invention, it will not be described in detail. In the present embodiment, the field shape and gain test are performed by taking the size specifications of the susceptor 3, the reflection frame 4, and the dipole antennas 5 shown in Tables 1 and 2 as an example.

Referring to the reflection loss test results shown in Figure 11, the array dipole antenna device has a low frequency band of -10 dB ranging from 2.0 GHz to 2.63 GHz, and a high frequency band of -10 dB ranging from 4.5 GHz to 6 GHz.

And the measured field patterns of 2.4 GHz, 2.5 GHz, 5 GHz, and 5.8 GHz shown in FIGS. 12A, 12B, 13A, 13B, 14A, 14B, 15A, and 15B show that in the low frequency range of 2.4 GHz and 2.5 GHz, E The field pattern of the face exhibits a figure of eight, and the field pattern of the H face is due to the first low frequency radiating arm 515, the second low frequency radiating arm 525, and the first microstrip line portion 518 and the matching The bottom-designed structure of the second microstrip line portion 528 concentrates the overall radiation upward, and the reflection of the reflecting plate 4 makes the H-face field more concentrated, and has directivity characteristics and increases the gain value. In the high frequency range of 5 GHz and 5.8 GHz, the H-plane and E-plane modes are similar to those in the low frequency range of 2.4 GHz and 2.5 GHz.

Referring to the gain test results of Figures 16 and 17, the low frequency gain is between 6.17 and 8.10 dBi, 2.49 GHz is the highest gain point of the low frequency, and the highest gain of the high frequency is 12.12 dBi, which falls at 5.2 GHz. The antenna device also has excellent gain characteristics.

Referring to Fig. 18, the second embodiment of the array dipole antenna device of the present invention differs from the first embodiment in the design of the overall structural shape. For convenience of description, only the differences between the present embodiment and the first embodiment will be described below.

In this embodiment, the array dipole antenna device is designed as a triangle, has a triangular base 3, a triangular reflective frame 4 disposed on the base 3, and three spaced symmetrically disposed on the base Dipole antenna 5 of three sides of three. In this embodiment, the distance between the end and the end of the adjacent two dipole antennas 5 is 10 mm, and the shortest distance between each dipole antenna 5 and the reflective frame 4 is 15 mm, but when implemented, it can be made according to the desired The bandwidth characteristics of the arrayed dipole antenna device are adjusted to adjust the relative positional relationship between the dipole antennas 5 and the reflection frame 4, and are not limited to the above spacing conditions.

Referring to Figures 19 and 20, it can be seen from the reflection loss graph of Fig. 19 that even if they are arranged in a triangle, the dipole antennas 5 also have good dual-frequency characteristics, and the isolation test results shown in Fig. 20 are known. The dipole antennas 5 do not affect the signal radiation performance of each other, and have good signal isolation.

From the field diagrams of Figs. 21A and 21B, in the low frequency range of 2.4 GHz and 2.5 GHz, the field modes of the E plane and the H plane are concentrated, and have directivity characteristics and increase the gain value. In the high frequency range of 5 GHz and 5.8 GHz, the H-plane and E-plane modes are similar to those in the low frequency range of 2.4 GHz and 2.5 GHz.

In summary, the structure of the first antenna body 51 and the second antenna body 52 through the dipole antennas 5 allows the dipole antenna 5 to have a double wide band in a miniaturized case. With good gain characteristics, it can be applied to WLAN system applications. In addition, by further providing the structural design of the reflective frame 4 between the dipole antennas 5, mutual interference between the dipole antennas 5 can be effectively avoided, and the array of the present invention can also be made in the case of downsizing. The dipole antenna device has excellent gain characteristics and can be applied to a multiple input multiple output (MIMO) wireless communication system. It is an innovative dipole antenna 5 and array dipole antenna device design. Therefore, the object of the present invention can be achieved.

However, the above is only the embodiment of the present invention, and the scope of the invention is not limited thereto, and all the simple equivalent changes and modifications according to the scope of the patent application and the patent specification of the present invention are still Within the scope of the invention patent.

3‧‧‧Base
4‧‧‧Reflection frame
41‧‧‧reflecting wall
5‧‧‧ dipole antenna
50‧‧‧Substrate
500‧‧‧Mirror symmetry line
501‧‧‧ first side
502‧‧‧ second side
51‧‧‧First antenna body
511‧‧‧First Antenna Section
512‧‧‧First high frequency radiation arm
513‧‧‧First high frequency longitudinal section
514‧‧‧First high frequency transverse section
515‧‧‧First low frequency radiation arm
516‧‧‧First low frequency transverse section
517‧‧‧First low frequency longitudinal section
518‧‧‧First microstrip line
52‧‧‧Second antenna body
521‧‧‧second antenna
522‧‧‧Second high-frequency radiation arm
523‧‧‧Second high frequency longitudinal section
524‧‧‧Second high frequency transverse section
525‧‧‧second low frequency radiating arm
526‧‧‧second low frequency transverse section
527‧‧‧second low frequency longitudinal section
528‧‧‧Second microstrip line

Other features and advantages of the present invention will be apparent from the following description of the drawings, wherein: Figure 1 is a perspective view of a first embodiment of an array dipole antenna device of the present invention; Figure 3 is a side view of the first embodiment; Figure 4 is a graph of the reflection loss of the single dipole antenna of the first embodiment; Figure 5A is the H-plane of the dipole antenna at the 2.4 GHz test. Field pattern, Figure 5B is the E-surface pattern of the dipole antenna at 2.4 GHz; Figure 6A is the H-field pattern of the dipole antenna at 2.5 GHz, and Figure 6B is the dipole antenna. Figure 6A shows the H-surface pattern of the dipole antenna at 5 GHz, and Figure 7B shows the E-surface pattern of the dipole antenna at 5 GHz; 8A is the H-field pattern of the dipole antenna tested at 5.8 GHz, and FIG. 8B is the E-face pattern of the dipole antenna at 5.8 GHz; FIG. 9 is the gain variation of the low-frequency band of the dipole antenna. FIG. 10 is a graph showing the gain variation of the high frequency band of the dipole antenna; FIG. 11 is the reflection loss curve of the first embodiment. Figure 12A is a view of the H-face field of the first embodiment at the 2.4 GHz test, and Figure 12B is a view of the E-face pattern of the first embodiment at the 2.4 GHz test; Figure 13A is the first embodiment The H-surface pattern at the 2.5 GHz test, FIG. 13B is the E-surface pattern at the 2.5 GHz test of the first embodiment; FIG. 14A is the H-surface pattern at the 5 GHz test of the first embodiment. Figure 14B is an E-surface pattern of the first embodiment at the 5 GHz test; Figure 15A is a H-field pattern of the first embodiment at 5.8 GHz, and Figure 15B is the first embodiment. Fig. 16 is a graph showing the gain variation of the low frequency band of the first embodiment; Fig. 17 is a graph showing the gain variation of the high frequency band of the first embodiment; Fig. 18 is a graph showing the gain variation of the low frequency band of the first embodiment; FIG. 19 is a top view of a second embodiment of the array dipole antenna device of the present invention; FIG. 19 is a graph showing reflection loss of a test conducted by three dipole antennas used in the second embodiment; FIG. 20 is the neighbor of the second embodiment. The isolation test curve between dipole antennas; FIG. 21A is the H-face field type of a dipole antenna in the second embodiment of the second embodiment. Figure 21B is an E-plane field diagram of a dipole antenna of the second embodiment at the 5 GHz test.

3‧‧‧Base

4‧‧‧Reflection frame

41‧‧‧reflecting wall

5‧‧‧ dipole antenna

50‧‧‧Substrate

501‧‧‧ first side

502‧‧‧ second side

51‧‧‧First antenna body

511‧‧‧First Antenna Section

518‧‧‧First microstrip line

52‧‧‧Second antenna body

521‧‧‧second antenna

528‧‧‧Second microstrip line

Claims (9)

A dipole antenna comprising: a substrate, an upright sheet extending left and right, having a first side and a second side opposite to each other, and defining two mirror-symmetric lines extending up and down and left and right; An antenna body is disposed on the first side, including two first antenna portions spaced apart from each other, and a first microstrip line portion connected between the first antenna portions, each of the first antennas a first HF radiating arm having an L-shape connected to the first microstrip line at one end and an L-shaped first low-frequency radiating arm; and a second antenna body disposed on the The second side surface includes two left and right spaced second antenna portions, and a second microstrip line portion connected between the second antenna portions, and each of the second antenna portions is shaped and disposed. One of the first antenna portions is mirror symmetrical along one of the mirror symmetry lines, and each of the second antenna portions has a second HF radiating arm connected to one another at one end and connected to the second microstrip line portion The second low frequency radiation arm. The dipole antenna according to claim 1, wherein each of the first high frequency radiating arms has a first high frequency longitudinal section extending up and down and having a bottom end connected to the end of the first microstrip line, and a Extending from a top end of the first high frequency longitudinal section to a first high frequency lateral section of the second high frequency radiating arm facing away from the mirror symmetry, each of the second high frequency radiating arms having a mirror symmetry with the first high frequency longitudinal section a second high frequency longitudinal section and a second high frequency transverse section mirror symmetrical with the first high frequency transverse section. The dipole antenna of claim 2, wherein each of the first low frequency radiating arms has a first low frequency lateral section connected to the corresponding first high frequency longitudinal section and extending away from the mirror symmetrical second low frequency radiating arm, And a first low frequency longitudinal section extending upward from the end of the first low frequency lateral section, each of the second low frequency radiating arms having a second low frequency transverse section mirror-symmetrical to the first low frequency lateral section, and one and the A low frequency longitudinal segment mirror symmetrical second low frequency longitudinal segment, and the first low frequency longitudinal segment is spaced apart from the second low frequency longitudinal segment of another second low frequency radiating arm that is not mirror symmetrical by a certain distance. An array dipole antenna device comprising: a pedestal; a reflection frame erectably disposed on a top surface of the susceptor for reflecting electric waves; and a plurality of dipole antennas disposed erectably on the top surface of the pedestal at intervals, and Each of the dipole antennas includes: a substrate extending horizontally from the top surface of the base, having a first side and a second side opposite to each other, and defining two upper and lower sides a first antenna body extending along the longitudinally spaced mirror symmetry line, a first antenna body disposed on the first side, including two first antenna portions spaced along the substrate, and one connected to the first antenna portion a first microstrip line portion between the first antenna portions, each of the first antenna portions having an L-shaped first high-frequency radiating arm and one connected to each other at one end and connected to the first microstrip line portion An L-shaped first low-frequency radiating arm, and a second antenna body disposed on the second side, including two second antenna portions disposed along the substrate at a long interval, and one connected to the second antenna Second microstrip line between antennas The shape and arrangement position of each of the second antenna portions is mirror symmetrical with one of the first antenna portions along one of the mirror symmetry lines, and each of the second antenna portions has one end connected to each other and connected to the second A second high frequency radiating arm of the microstrip line portion and a second low frequency radiating arm. The array dipole antenna device according to claim 4, wherein the reflection frame is in a triangular ring shape, and has three reflective walls which are sequentially connected to form an annular shape, and the array dipole antenna device includes three dipole antennas. And the dipole antennas are spaced apart from the reflective walls. The array dipole antenna device according to claim 4, wherein the reflection frame is in a quadrangular ring shape, and has four reflective walls which are sequentially connected to form a ring, and the array dipole antenna device includes four dipole antennas. The dipole antennas are spaced apart from the reflective walls. The array dipole antenna device of 5 or 6, wherein a top edge of the reflective frame is higher than a top edge of the dipole antennas. The array dipole antenna device of 5 or 6, wherein each of the first high frequency radiating arms has a first high frequency longitudinal section extending up and down and having a bottom end connected to the end of the first microstrip line, and a first high frequency transverse section extending outwardly from the top end of the first high frequency longitudinal section away from the mirror symmetrical second high frequency radiating arm, each second high frequency radiating arm having a mirror image of the first high frequency longitudinal section a symmetrical second high frequency longitudinal section and a second high frequency transverse section mirror symmetrical with the first high frequency transverse section. The array dipole antenna device of claim 8, wherein each of the first low frequency radiating arms has a first low frequency lateral direction coupled to the corresponding first high frequency longitudinal section and extending away from the mirror symmetrical second low frequency radiating arm a segment, and a first low frequency longitudinal segment extending upward from an end of the first low frequency lateral segment, each second low frequency radiating arm having a second low frequency transverse segment mirror symmetrical with the first low frequency lateral segment, and a The first low frequency longitudinal segment is mirror symmetrical to the second low frequency longitudinal segment, and the first low frequency longitudinal segment is spaced apart from the second low frequency longitudinal segment of the other second low frequency radiating arm that is not mirror symmetrical by a certain distance.